JP2020200647A - Column adjusting body, column, and external structural fixture - Google Patents

Abstract

To provide a column adjusting body capable of adjusting a column erection after the hardening of ready-mixed concrete, a column, and an external structural fixture.SOLUTION: A column adjusting body 10 includes a column base body 7 having an upper surface 222, a column mounting member 70 having side plate parts 73, 74 to which the column body can be attached, and an adjusting unit 11. The adjusting unit 11 is made up of a tilting adjusting mechanism 30 capable of adjusting the tilt of the column mounting member 70 with respect to the upper surface 222 of the column base body 7 and a movement adjusting mechanism 50 capable of adjusting the movement of the column mounting member 70 along the upper surface 222 of the column base body 7. The column mounting member 70 is supported by the adjusting unit 11 so that the positions of the side plate parts 73, 74 around the axis along the Y-axis direction of the adjusting unit 11 can be adjusted in rotation.SELECTED DRAWING: Figure 2

Description

The present invention relates to a pillar adjusting body, a pillar, and an exterior fitting for adjusting the installation of pillars such as a flip-up gate.

Conventionally, a gate is known in which left and right gate pillars (pillars) are erected on the ground and gates are attached to the left and right gate pillars, respectively (see Patent Document 1). The gate pillar is erected on the ground by inserting the lower part into a hole provided in the ground, placing ready-mixed concrete in this hole, and hardening the placed ready-mixed concrete. The gate is hung from the gate pillar while being supported by a jig installed between the gate pillars.

Japanese Unexamined Patent Publication No. 5-5387

By the way, in the gate described in Patent Document 1, the gate pillar is affected by the wind, the weight of the gate pillar, and the like during the casting and curing period of the ready-mixed concrete put into the hole provided in the ground. There is a risk of misalignment, and if the ready-mixed concrete hardens with the installation misaligned, it is difficult to adjust the installation of the gate pillars.

An object of the present invention is to provide a column adjuster, a column and an exterior fitting that can adjust the installation of columns after the ready-mixed concrete is hardened.

The column adjusting body of the present invention is a column adjusting body to which a column body is attached, and has a column base having an upper surface orthogonal to the vertical direction of the column body and a column having an attachment portion to which the column body can be attached. It is composed of a mounting member, a tilt adjusting mechanism capable of tilting and adjusting the pillar mounting member with respect to the upper surface of the pillar base, and a movement adjusting mechanism capable of adjusting the movement of the pillar mounting member along the upper surface of the pillar base. The pillar mounting member is supported by the adjusting unit so that the position of the mounting portion around the axis along the vertical direction of the adjusting unit can be rotatably adjusted.
The pillar of the present invention is characterized by including the above-mentioned pillar adjusting body of the present invention and a pillar main body attached to the pillar adjusting body.
The exterior fitting of the present invention is characterized by including the pillar of the present invention described above and a door body supported by the pillar.

According to the present invention, it is possible to provide a column adjusting body, a column and an exterior fitting that can adjust the installation of columns after the ready-mixed concrete is hardened.

The perspective view which shows the installation state of the pillar adjusting body which concerns on embodiment of this invention. The perspective view which shows the pillar adjustment body which concerns on the said embodiment. The perspective view which shows the pillar adjusting body which concerns on the said Embodiment in the developed form. The perspective view which shows the installation of the pillar adjustment body which concerns on the said embodiment. Explanatory drawing which shows the installation of the pillar provided with the pillar adjusting body which concerns on the said embodiment. The explanatory view which shows the tilt adjustment in the depth direction by the pillar adjustment body which concerns on the said embodiment. The explanatory view which shows the tilt adjustment in the frontage direction by the pillar adjustment body which concerns on the said embodiment. The explanatory view which shows the height position adjustment by the pillar adjustment body which concerns on the said embodiment. The explanatory view which shows the position adjustment in the depth direction and the frontage direction by the pillar adjustment body which concerns on the said embodiment. The explanatory view which shows the pillar direction adjustment by the pillar adjustment body which concerns on the said embodiment. The perspective view which shows the installation of the pillar provided with the pillar adjusting body which concerns on the said embodiment.

[Structure of the present embodiment]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In FIGS. 1 and 2, the pillar adjusting body 10 according to the present embodiment is incorporated into the left and right pillars 5 of the flip-up gate 1 (see FIG. 5A) as an exterior fitting. The flip-up gate 1 includes left and right pillars 5 erected on the ground 2, a rotating arm 3 rotatably attached to the left and right pillars 5, and a door body 4 attached to the rotating arm 3. It is composed of. The left and right pillars 5 include a pillar adjusting body 10 installed on the ground 2 and a pillar main body 6 having a substantially hollow rectangular cross section attached to the pillar adjusting body 10.
In the following description, the frontage direction of the flip-up gate 1 (horizontal direction of the pillar 5) is the X-axis direction, and the vertical direction of the flip-up gate 1 (the vertical direction of the pillar 5) is the Y-axis direction. The depth direction of the gate 1 (depth direction of the pillar 5) is the Z-axis direction. The X, Y, and Z axis directions are orthogonal to each other.

As shown in FIGS. 2 and 3, the column adjusting body 10 includes a column base 7 having a rectangular cross section embedded in a hole 21 (see FIG. 4) formed in the ground 2 and an adjusting unit 11 attached to the column base 7. And a pillar mounting member 70 supported by the adjusting unit 11.
The pillar base 7 is composed of a hollow rectangular embedded member 7A embedded in a hole 21 formed in the ground 2 and a fixing member 20 having a U-shaped cross section fixed to the embedded member 7A. The fixing member 20 includes an upper plate portion 22 having an upper surface 222 orthogonal to the Y-axis direction, and a pair of side plate portions 23, 24 extending downward from both edges of the upper plate portion 22 along the X-axis direction. It has a U-shaped cross section. The upper plate portion 22 is formed with two screw holes 221 into which the connecting screw 322 (tap screw) described later is screwed. Two fixing holes 25 are formed in the side plate portions 23 and 24. The fixing member 20 is screwed to the embedding member 7A by screwing a fixing screw 26 (tap screw) as a fixing tool inserted into the embedding member 7A into the fixing hole 25.
The adjusting unit 11 tilts around a first moving member 31 movably connected to the column base 7 in the depth direction thereof and an axial center orthogonal to the first moving member 31 in the vertical direction and the depth direction thereof. A first tilting member 41 that is movably connected, a second moving member 51 that is movably connected to the first tilting member 41 in the left-right direction, and a second moving member 51 that is vertically and horizontally connected to the second moving member 51. A second tilting member 61 that is tiltably connected around an axis orthogonal to the direction is provided, and a first tilting member 41 that is tiltably connected to the first moving member 31 and the second moving member 51. The tilt adjusting mechanism 30 is composed of the second tilting member 61 and the first moving member 31 and the second moving member 51 movably connected to the column base 7 and the first tilting member 41. 50 is configured. The second tilting member 61 supports the pillar mounting member 70.
The pillar mounting member 70, the fixing member 20, the first moving member 31, the first tilting member 41, the second moving member 51, and the second tilting member 61 are made of a metal material such as stainless steel (SUS) or steel.

The first moving member 31 includes a lower plate portion 32 in which two guide holes 321 are formed along the Z-axis direction, and a pair of side plates extending upward from both edges of the lower plate portion 32 along the Z-axis direction. It has portions 33 and 34 and is formed in a U-shaped cross section. A connecting screw 322 as a connecting shaft is inserted into each guide hole 321, and the connecting screw 322 is screwed into the screwing hole 221 in the upper plate portion 22 of the fixing member 20. Therefore, the first moving member 31 is immovably fixed to the fixing member 20 by tightening the connecting screw 322, while being guided to the guide hole 321 with respect to the fixing member 20 by loosening the connecting screw 322. However, it becomes movable in the Z-axis direction. Further, the pair of side plate portions 33, 34 are formed with screw holes 36 into which a shaft screw 45 as a connecting shaft, which will be described later, is screwed.

The first tilting member 41 is formed in a U-shaped cross section by the upper plate portion 42 and a pair of side plate portions 43, 44 extending downward from both edges of the upper plate portion 42 along the Z-axis direction. .. The upper plate portion 42 is formed with two screw holes 421 into which a connecting screw 522 (tap screw) as a connecting shaft, which will be described later, is screwed. The side plate portions 43 and 44 are formed with a shaft hole 46 into which a shaft screw 45 (tap screw) is inserted, a fixing hole 47, and a preliminary fixing hole 48. The first tilting member 41 has a shaft screw 45 inserted into each shaft hole 46 and screwed into the screw hole 36 in the side plate portions 33 and 34 of the first moving member 31 with respect to the first moving member 31. It is in a state where it can be tilted in the XR direction with the shaft screw 45 as the axis. Further, in the first tilting member 41, a fixing screw 471 (drill screw) as a fixing tool is inserted into the fixing hole 47 and screwed into the side plate portions 33 and 34 of the first moving member 31, so that the first moving member 31 It is screwed so that it cannot tilt.

The second moving member 51 includes a lower plate portion 52 in which two guide holes 521 are formed along the X-axis direction, and a pair of side plates extending upward from both edges of the lower plate portion 52 along the X-axis direction. It has portions 53 and 54 and is formed in a U-shaped cross section. A connecting screw 522 is inserted into each guide hole 521, and the connecting screw 522 is screwed into the screw hole 421 in the upper plate portion 42 of the first tilting member 41. Therefore, the second moving member 51 is immovably fixed to the first tilting member 41 by tightening the connecting screw 522, while the guide hole is fixed to the first tilting member 41 by loosening the connecting screw 522. While being guided by 521, it becomes movable in the X-axis direction. Further, the pair of side plate portions 53 and 54 are formed with screw holes 56 into which a shaft screw 65 (tap screw) as a connecting shaft described later is screwed.

The second tilting member 61 includes an upper plate portion 62 on which a shaft portion 621 projecting upward is formed, and a pair of side plate portions 63, 64 extending downward from both edges of the upper plate portion 62 along the X-axis direction. It is formed in a U-shaped cross section by. The shaft portion 621 is arranged at the center position of the upper plate portion 62. A nut 622 is screwed into the shaft portion 621. The side plate portions 63 and 64 are formed with a long shaft hole 66, a fixing hole 67, and a preliminary fixing hole 68 along the Y-axis direction through which the shaft screw 65 is inserted. The second tilting member 61 has a shaft screw 65 inserted into each shaft elongated hole 66 and screwed into the screw hole 56 in the side plate portions 53 and 54 of the second moving member 51 with respect to the second moving member 51. The shaft screw 65 can be tilted in the ZR direction with the shaft screw 65 as the axis, and can be moved in the Y-axis direction along the long shaft hole 66. Further, in the second tilting member 61, a fixing screw 671 (drill screw) as a fixing tool is inserted into the fixing hole 67 and screwed into the side plate portions 53 and 54 of the second moving member 51, whereby the second moving member 51 It is screwed so that it cannot tilt and move up and down.

The pillar mounting member 70 has a top plate portion 72 and a pair of side plate portions 73, 74 (mounting portions) extending downward from both edges of the top plate portion 72 along the X-axis direction, and has a U-shaped cross section. It is formed in a shape. The upper plate portion 72 is formed with a shaft hole 721 through which the shaft portion 621 of the second tilting member 61 is inserted, a fixing hole 77, and a preliminary fixing hole 78. The shaft hole 721 is arranged at the center position of the upper plate portion 72. Two fixing holes 79 are formed in the side plate portions 73 and 74. The column mounting member 70 can rotate in the YR direction with the shaft portion 621 along the Y-axis direction as the axis, and the fixing screw 76 (drill screw) as a fixture is inserted into the fixing hole 77 to insert the second tilting member 61. By being screwed into the upper plate portion 62, it is screwed to the second tilting member 61 so as not to rotate. The side plate portions 73 and 74 are arranged at a wide interval D (see FIG. 6A) so as to be rotatable in the XR direction by at least 90 ° (360 ° in this embodiment) around the second tilting member 61. Has been done. The pillar body 6 is attached to the side plate portions 73 and 74 by inserting a fixing screw 75 as a fixing tool into the pillar body 6 and screwing it into the fixing hole 79.

Hereinafter, the installation adjustment of the pillar 5 by the pillar adjusting body 10 according to the present embodiment will be described.
First, as shown in FIG. 4, the embedded member 7A of the pillar adjusting body 10 is inserted into the left and right holes 21 formed in the ground 2 from above. In the present embodiment, the pillar mounting members 70 of the left and right pillar adjusting bodies 10 are connected to each other by using the connecting member 100 along the X-axis direction, so that the pillar base 7 is arranged so as to suppress the installation deviation as much as possible. Next, ready-mixed concrete 101 (see FIG. 1) is cast into each hole 21 and cured. Here, the column base 7 may be displaced due to the influence of external factors such as wind, and the ready-mixed concrete 101 may be hardened in that state. If the column body 6 is installed as it is, it will be installed on the column 5. The gap remains. As for the installation deviation of the pillar 5, the tilt in the Z-axis direction (depth direction) shown in FIG. 5 (A), the tilt in the X-axis direction (frontage direction (left-right direction)) shown in FIG. 5 (B), and FIG. 5 ( The displacement in the Y-axis direction (vertical direction) shown in C), the displacement in the direction of the pillar shown in FIG. 5 (D), and the displacement of the pillar 5 shown in FIG. 5 (E) in the X-axis direction and the Z-axis direction is there. If there is a gap in the installation in this way, the installation will be adjusted. In this embodiment, the installation adjustment is performed according to the following procedure. The connecting material 100 is removed after the ready-mixed concrete 101 has hardened.

In the present embodiment, the pillar adjusting body 10 performs the installation adjustment through the first adjustment procedure to the seventh adjustment procedure described later.
In the first adjustment procedure, the tilt of the column base 7 in the Z-axis direction is adjusted. Specifically, as shown in FIG. 6A, the first tilting member 41 is tilted in the XR direction with respect to the first moving member 31 in a state where the shaft screw 45 is loosened by a tool such as a screwdriver or a spanner. As shown in FIG. 6B, the side plate portions 73 and 74 of the column mounting member 70 are in a state along the Y-axis direction, and the shaft screw 45 is tightened. As a result, the inclination T1 in the depth direction shown in FIG. 5A in the state where the pillar body 6 is attached to the pillar attachment member 70 is not adjusted.
In the second adjustment procedure, the tilt of the column base 7 in the X-axis direction is adjusted. Specifically, as shown in FIG. 7A, the pillar mounting member 70 is rotated by about 90 ° in the YR direction to make the shaft screw 65 rotatable, and then the shaft screw 65 is loosened by a tool. The second tilting member 61 is tilted with respect to the second moving member 51 in the ZR direction, and the side plate portions 73 and 74 of the column mounting member 70 are in a state along the Y-axis direction as shown in FIG. 7B. As a result, the inclination T2 in the frontage direction shown in FIG. 5B in the state where the pillar body 6 is attached to the pillar attachment member 70 is not adjusted.
In the third adjustment procedure, the positional deviation of the column base 7 in the Y-axis direction is adjusted. Specifically, as shown in FIGS. 8A and 8B, following the second adjustment procedure, the second tilting member 61 is Y with respect to the second moving member 51 along the long hole 66. Move in the axial direction to adjust the height position of the pillar mounting member 70, and tighten the shaft screw 65. As a result, the height position deviation H shown in FIG. 5C in the state where the pillar body 6 is attached to the pillar attachment member 70 is not adjusted.
In the fourth adjustment procedure, the positional deviation of the column base 7 in the X-axis direction is adjusted. Specifically, as shown in FIG. 9A, the connecting screw 522 is loosened by a tool to move the second moving member 51 with respect to the first tilting member 41 along the guide hole 521 in the X-axis direction to connect the second moving member 51. Tighten the screw 522. As a result, the positional deviation in the frontage direction when the pillar body 6 is attached to the pillar mounting member 70 is not adjusted, and the distance W1 between the left and right pillars 5 is increased as shown in FIGS. 5 (D) and 5 (E). It can be set at predetermined intervals. In FIG. 9A, for convenience of explanation, a part of the adjustment unit 11 and the pillar mounting member 70 are not shown.
In the fifth adjustment procedure, the positional deviation of the column base 7 in the Z direction is adjusted. Specifically, as shown in FIG. 9B, the connecting screw 322 is loosened by a tool, the first moving member 31 is moved along the guide hole 321 in the Z-axis direction, and the connecting screw 322 is tightened. As a result, the positional deviation in the depth direction when the pillar body 6 is attached to the pillar attachment member 70 is not adjusted. In FIG. 9B, for convenience of explanation, a part of the adjustment unit 11 and the pillar mounting member 70 are not shown.
In the sixth adjustment procedure, the column mounting member 70 is rotated in the YR direction with respect to the deviation of the column base 7 in the direction around the axis along the Y-axis direction. Specifically, with the nut 622 loosened by a tool, the pillar mounting member 70 is rotated in the YR direction around the shaft portion 621 as shown in FIG. 10 (A), and the predetermined shape shown in FIG. 10 (B) is determined. Arrange in the orientation and tighten the nut 622. As a result, the direction of the pillar in the state where the pillar body 6 is attached to the pillar mounting member 70 is adjusted from the state shown in FIG. 5 (D) to the parallel state shown in FIG. 5 (E), and the pillar shown in FIG. 5 (D). The intervals W1 and W2 between 5 are the same.
In the seventh adjustment procedure, the final installation adjustment of each of the above-mentioned parts is performed, and each part is retightened and fixed. Specifically, the shaft screws 45 and 65, the connecting screws 322 and 522, and the nut 622 are retightened, and the fixing screw 76 is inserted into the fixing hole 77 and screwed into the upper plate portion 62 of the second tilting member 61 to fix the screw. , Fixing by inserting the fixing screw 471 into the fixing hole 47 and screwing it into the side plate portions 33 and 34 of the first moving member 31, and inserting the fixing screw 671 into the fixing hole 67 and inserting the fixing screw 671 into the side plate portions 53 and 54 of the second moving member 51. It is fixed by screwing it into. In addition, various fixing screws are inserted into the preliminary fixing holes 48, 68, 78 when the installation adjustment by the column adjusting body 10 is performed again.
In this way, the installation adjustment is performed by the pillar adjusting body 10. In this embodiment, the installation adjustment was performed through the first adjustment procedure to the seventh adjustment procedure, but the first adjustment procedure to the sixth adjustment procedure are performed according to the occurrence of the column base 7 falling, the position and the orientation deviation. The order of the above may be changed, and when the adjustments in the first to sixth adjustment procedures are unnecessary, the unnecessary adjustment steps may be omitted.

After the installation adjustment by the column adjusting body 10, as shown in FIG. 11, the column body 6 is screwed to the side plate portions 73 and 74 of the column mounting member 70 with fixing screws 75, and the column cover 8 is attached to the column body 6. To do. Then, the pillar body 6 is passed through the cap 9, and the cap 9 covers the gap between the pillar body 6 and the ground 2 to fix the cap 9. In this way, the pillar 5 is configured, and the pillar adjusting body 10 is arranged so as not to be exposed to the outside by the cap 9.

[Modification example]
In the above embodiment, the adjustment unit 11 includes a first moving member 31, a second moving member 51, a first tilting member 41, and a second tilting member 61. For example, a separate installation adjustment is performed on the pillar 5. When the mechanism is configured, the first moving member 31, the second moving member 51, the first tilting member 41, and the second tilting member 61 are arranged according to the movement and inclination that can be adjusted by the installation adjustment mechanism. Either member may be omitted, or any member may be replaced with a fixed member that does not move or tilt. Further, in the above embodiment, the first tilting member 41 is connected to the first moving member 31, the second moving member 51 is connected to the first tilting member 41, and the second tilting member 61 is connected to the second moving member 51. However, the connection order is not limited to this, for example, the second moving member 51 is connected to the first moving member 31, the second tilting member 61 is connected to the second moving member 51, and the second tilting member 61 is connected. The first tilting member 41 may be connected to the. In this case, the shape of each member may be appropriately changed to a shape such as an L shape or a box shape.
In the above embodiment, the axial long hole 66 is formed in the second tilting member 61 and the screw hole 56 is formed in the second moving member 51, but conversely, the second tilting member 61 is screwed. A hole may be formed and an axial elongated hole may be formed in the second moving member 51. In this case, the shaft screw 65 is inserted into the long shaft hole from the opposite surface side of the pair of side plate portions 54 of the second moving member 51 and screwed into the screw hole. Further, instead of or in addition to the above-described configuration, an axial elongated hole is formed in one of the first moving member 31 and the second tilting member 61 along the vertical direction, and a screw hole is formed in the other. , The shaft screw 45 may be inserted into the shaft elongated hole and screwed into the screw hole. When it is not necessary to adjust the height position of the pillar body 6 by the adjusting unit 11, the elongated shaft hole 66 may be changed to a perfectly circular shaft hole.
In the above embodiment, the first tilting member 41 and the second tilting member 61 have an outset configuration that covers the first moving member 31 and the second moving member 51, respectively, but the present invention is not limited to this, and the first tilting member 41 and the second tilting member 61 are not limited to this. The two tilting member 61 may have an inset configuration in which the first moving member 31 and the second moving member 51 enter inside.
In the above embodiment, the adjusting unit 11 is configured to be tilt-adjustable in the XR direction and the ZR direction by including the first tilting member 41 and the second tilting member 61, but is not limited to this, and is not limited to this, for example, by a ball joint. It may be configured to be tiltable.
In the above-described embodiment, the first tilting member 41, the second tilting member 61, and the column mounting member 70 are formed with preliminary fixing holes 48, 68, 78 for mounting readjustment, but the building readjustment can be performed. If it is not necessary to provide the preliminary fixing holes 48, 68, 78, the configuration may be omitted.
In the above embodiment, two guide holes 321 and 521 are formed in each of the first moving member 31 and the second moving member 51, but three or more guide holes may be formed in each. Further, only one guide hole 321 and 521 may be formed, but in this case, two or more connecting screws 322 and 522 separated by a predetermined interval are inserted into the guide holes 321 and 521. However, one connecting screw 322,522 may be inserted.
In the above embodiment, the shaft portion 621 is formed in the second tilting member 61 and the shaft hole 721 is formed in the pillar mounting member 70, but the present invention is not limited to this, and the shaft hole is formed in the second tilting member 61. A shaft portion extending downward is formed in the column mounting member 70, and this shaft portion may be inserted through the shaft hole.
In the above embodiment, the side plate portions 73 and 74 of the column mounting member 70 are formed so as to extend downward from the upper plate portion 72, but are not limited to this, and are formed so as to extend upward from the upper plate portion 72. You may be.
In the above-described embodiment, the flip-up type gate 1 has been described as an exterior fitting, but other types of gates, fences, and the like may be used.

[Summary of the present invention]
The column adjusting body of the present invention is a column adjusting body to which a column body is attached, and has a column base having an upper surface orthogonal to the vertical direction of the column body and a column having an attachment portion to which the column body can be attached. It is composed of a mounting member, a tilt adjusting mechanism capable of tilting and adjusting the pillar mounting member with respect to the upper surface of the pillar base, and a movement adjusting mechanism capable of adjusting the movement of the pillar mounting member along the upper surface of the pillar base. The pillar mounting member is supported by the adjusting unit so that the position of the mounting portion around the axis along the vertical direction of the adjusting unit can be rotatably adjusted.
According to the column adjusting body of the present invention, for example, when a column base is placed in a hole formed in a foundation and ready-mixed concrete is cast in the hole to harden it, the influence of external factors such as wind during curing is affected. In response to this, even if the upper surface of the pillar base is tilted with respect to the horizontal plane, or the pillar base is displaced in the left-right direction or the depth direction, the pillar mounting member is mounted by the tilt adjustment mechanism. The inclination of the pillar mounting member can be adjusted to a predetermined tilt by tilting with respect to the upper surface of the base, and the pillar mounting member can be moved along the upper surface of the pillar base by the movement adjusting mechanism in the left-right direction of the pillar mounting member. The position in the depth direction can be adjusted to a predetermined position, and the rotation position of the mounting portion of the pillar mounting member can be adjusted to the predetermined rotation position by rotating the pillar mounting member around the axis along the vertical direction of the adjusting unit. .. Therefore, it is possible to adjust the inclination of the pillar body to be mounted on the mounting portion of the pillar mounting member, the positions in the left-right direction and the depth direction, and the orientation around the axis along the vertical direction.

In the pillar adjusting body of the present invention, the adjusting unit can be tilted in the depth direction with respect to the first moving member connected to the pillar base so as to be movable in the depth direction and the first moving member. The connected first tilting member, the second moving member movably connected to the first tilting member in the left-right direction, and the second moving member movably connected to the second moving member in the left-right direction. The tilt adjusting mechanism is configured by the first tilting member and the first tilting member and the second tilting member that are tiltably connected to the first moving member and the second moving member. The movement adjusting mechanism may be composed of the first moving member and the second moving member movably connected to the pillar base and the first tilting member.
According to such a configuration, the positions of the pillar mounting member in the depth direction and the left-right direction can be adjusted by moving the first moving member and the second moving member, and the pillar mounting member can be adjusted by tilting the first tilting member and the second tilting member. The inclination in the depth direction and the left-right direction can be adjusted, and the rotation position of the mounting portion around the axis along the vertical direction can be adjusted by the rotation of the pillar mounting member.
Further, since the adjusting unit is configured by connecting the first moving member, the first tilting member, the second moving member, and the second tilting member, the first moving member can be moved in the depth direction and the second tilting member can be moved. The tilting in the depth direction, the left-right movement of the second moving member, and the left-right tilting of the second tilting member can be performed independently, and the workability of the installation adjustment can be improved.

In the column adjusting body of the present invention, the first moving member and the second moving member each have a lower plate portion and a pair of side plate portions extending upward from the lower plate portion, and the first tilting member and the first tilting member The second tilting member has an upper plate portion and a pair of side plate portions extending downward from the upper plate portion, and the first tilting member and each side plate portion of the second tilting member are the first. The moving member and each side plate portion of the second moving member are tiltably connected by a connecting shaft, and the first tilting member and the second tilting member are connected to the first moving member and the second moving member. A fixing hole through which a fixture fixed to each side plate can be inserted may be formed.
According to such a configuration, the first tilting member is tilted with respect to the first moving member around the connecting shaft, and the second tilting member is tilted with respect to the first moving member around the connecting shaft. With, the inclination of the pillar mounting member can be adjusted. Further, after adjusting the inclination, the first tilting member can be easily fixed to the first moving member by inserting a fixture into the fixing hole of the first tilting member and fixing it to each side plate portion of the first moving member. The second tilting member can be easily fixed to the second moving member by inserting the fixing tool into the fixing hole of the second tilting member and fixing it to each side plate portion of the second moving member. Since the first tilting member and the second tilting member can be fixed independently in this way, the tilt adjustment in the depth direction and the tilt adjustment in the left-right direction of the column mounting member can be performed separately, and the installation adjustment work. Can improve sex.

In the pillar adjusting body of the present invention, an axial elongated hole is formed in each side plate portion of one of the second moving member and the second tilting member along the vertical direction through which the connecting shaft is inserted. The connecting shaft may be fixed to each of the other side plates.
According to such a configuration, since the connecting shaft is inserted through the axial elongated hole along the vertical direction, the second tilting member can be moved up and down with respect to the second moving member, thereby increasing the height of the column mounting member. The position can be adjusted.
Further, for example, one side plate portion of the first moving member and the first tilting member is formed with an axial elongated hole along the vertical direction, and the connecting shaft is inserted into the axial elongated hole and is inserted into the other side plate portion. When it is fixed and the first tilting member is configured to be vertically movable with respect to the first moving member, the vertical load of the second moving member and the second tilting member is applied to the first tilting member, so that the pillar is attached. In contrast to the fact that it is difficult to improve workability because it requires force to adjust the height position of the member, in the present invention, the second tilting member is moved up and down with respect to the second moving member, so that the second tilting member is moved up and down. It is possible to improve the workability of adjusting the height position of the column mounting member without requiring a large force as described above for moving the column up and down.

In the pillar adjusting body of the present invention, a guide hole is formed in the lower plate portion of the first moving member along the depth direction and through which a connecting shaft fixed to the pillar base is inserted. A guide hole may be formed in the lower plate portion of the member along the left-right direction and through which a connecting shaft fixed to the upper plate portion of the first tilting member is inserted.
According to such a configuration, the first moving member can be moved in the depth direction along the guide hole with respect to the column base, and the second moving member can be moved in the left-right direction along the guide hole with respect to the first tilting member. It can be moved to, which allows the position of the column mounting member to be adjusted in the depth direction and the left-right direction.

In the pillar adjusting body of the present invention, the adjusting unit is formed with a shaft portion protruding upward, the pillar mounting member is formed with a shaft hole through which the shaft portion is inserted, and the pillar mounting member is formed. It may be rotatably supported by the adjusting unit around the shaft.
According to such a configuration, the rotation position of the mounting portion can be adjusted by rotating the pillar mounting member, whereby the orientation around the axis center along the vertical direction of the pillar body mounted on the mounting portion can be adjusted.

The column of the present invention is characterized by including a column body attached to the column adjusting body.
According to the pillar of the present invention, it is possible to construct a pillar capable of exerting the same action and effect as the action and effect of the pillar adjuster of the present invention described above.

The exterior fitting of the present invention is characterized by including the pillar of the present invention described above and a door body supported by the pillar.
According to the exterior fittings of the present invention, it is possible to construct an exterior fittings capable of exerting the same effects as those of the pillars of the present invention described above.

1 ... flip-up gate (outside fittings), 10 ... pillar adjuster, 101 ... ready-mixed concrete, 11 ... adjustment unit, 20 ... fixing member, 22, 42, 62, 72 ... upper plate, 221, 36, 421 , 56 ... Screw holes, 23,24,33,34,43,44,53,54,63,64,73,74 ... Side plate parts, 25,47,67,77,79 ... Fixing holes, 26,471 , 671, 75, 76 ... Fixing screw (fixing tool), 30 ... Tilt adjusting mechanism, 31 ... First moving member, 32, 52 ... Lower plate, 321, 521 ... Guide hole, 322, 522 ... Connecting screw (connecting) Shaft), 45, 65 ... Shaft screw (connecting shaft), 46,721 ... Shaft hole, 48, 68, 78 ... Preliminary fixing hole, 5 ... Pillar, 50 ... Movement adjustment mechanism, 51 ... Second moving member, 6 ... Pillar body, 61 ... Second tilting member, 621 ... Shaft, 622 ... Nut, 66 ... Shaft slot, 7 ... Pillar base, 70 ... Pillar mounting member, 7A ... Embedded member, 9 ... Cap, D ... Spacing, H ... Height position deviation, T1, T2 ... Tilt, W1, W2 ... Interval.

Claims (8)

It is a pillar adjustment body to which the pillar body is attached.
A pillar base having an upper surface orthogonal to the vertical direction of the pillar body,
A pillar mounting member having a mounting portion to which the pillar body can be mounted,
An adjustment unit composed of a tilt adjusting mechanism capable of tilting and adjusting the pillar mounting member with respect to the upper surface of the pillar base, and a movement adjusting mechanism capable of adjusting the movement of the pillar mounting member along the upper surface of the pillar base. With
The pillar mounting member is a pillar adjusting body characterized in that the position of the mounting portion around an axis along the vertical direction of the adjusting unit is supported by the adjusting unit so as to be rotatable and adjustable. In the pillar adjusting body according to claim 1,
The adjusting unit includes a first moving member movably connected to the pillar substrate in the depth direction thereof, and a first tilting member movably connected to the first moving member in the depth direction thereof. A second moving member that is movably connected to the first tilting member in the left-right direction and a second tilting member that is movably connected to the second moving member in the left-right direction. ,
The tilt adjusting mechanism is configured by the first tilting member and the second tilting member that are tiltably connected to the first moving member and the second moving member.
A pillar adjusting body, characterized in that the movement adjusting mechanism is composed of the first moving member and the second moving member movably connected to the pillar base and the first tilting member. In the pillar adjusting body according to claim 2,
The first moving member and the second moving member each have a lower plate portion and a pair of side plate portions extending upward from the lower plate portion.
The first tilting member and the second tilting member each have an upper plate portion and a pair of side plate portions extending downward from the upper plate portion.
Each side plate portion of the first tilting member and the second tilting member is tiltably connected to each side plate portion of the first moving member and the second moving member by a connecting shaft.
The first tilting member and the second tilting member are characterized in that a fixing hole through which a fixture fixed to each side plate portion of the first moving member and the second moving member can be inserted is formed. Pillar adjustment body to do. In the pillar adjusting body according to claim 3,
An axial elongated hole is formed in each side plate portion of one of the second moving member and the second tilting member along the vertical direction through which the connecting shaft is inserted, and each side plate portion of the other side plate portion is formed. A column adjusting body characterized in that the connecting shaft is fixed. In the pillar adjusting body according to claim 1 or 4.
A guide hole is formed in the lower plate portion of the first moving member along the depth direction and through which a connecting shaft fixed to the pillar base is inserted.
The lower plate portion of the second moving member is characterized in that a guide hole is formed along the left-right direction and through which a connecting shaft fixed to the upper plate portion of the first tilting member is inserted. Pillar adjuster. In the pillar adjusting body according to any one of claims 1 and 5.
The adjusting unit is formed with a shaft portion that protrudes upward.
A shaft hole through which the shaft portion is inserted is formed in the pillar mounting member.
The pillar adjusting body is characterized in that the pillar mounting member is rotatably supported by the adjusting unit around the shaft portion. The pillar adjusting body according to any one of claims 1 to 6,
A pillar characterized by having a pillar body attached to the pillar adjusting body. An exterior fitting comprising the pillar according to claim 7 and a door body supported by the pillar.

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